Key Laboratory of Intelligent Computing and Signal Processing of Ministry of Education, School of Electronics and Information Engineering , Anhui University , 111 Jiulong Road , Hefei , Anhui 230601 , P. R. China.
School of Optical and Electronic Information , Huazhong University of Science and Technology , 1037 Luoyu Road , Wuhan , Hubei 430074 , P. R. China.
ACS Appl Mater Interfaces. 2019 Oct 30;11(43):40716-40725. doi: 10.1021/acsami.9b16511. Epub 2019 Oct 21.
Three-dimensional (3D) porous conductive composites explored in highly sensitive tactile sensors have attracted extensive close attention in recent years owing to their peculiar porous structure and unique physical properties in terms of excellent mechanical flexibility, high relative dielectric permittivity, and good elastic property. Herein, we report an practical, efficient, and macroscopic dip-coating process to manufacture rapid-response, low detection limit, high-sensitivity, and highly sensitive capacitive flexible tactile sensors. The fabrication process, tactile perception mechanism, and sensing performance of the developed devices are comparatively investigated. The homogeneous 3D hybrid network constructed by graphene nanoplatelets/carboxyl-functionalized multiwalled carbon nanotubes/silicone rubber composites anchored on polyurethane sponge skeletons exhibits a significantly improved dielectric property, resulting in a high-performance capacitive flexible tactile sensor with a fast response time (∼45 ms), an extremely low-pressure detection limit of ∼3 Pa, excellent sensitivity (∼0.062 kPa), and excellent durability and stability over 2000 cycles. Importantly, the flexible devices can be used as the wearable electronic skin and successfully mounted on human skin or a soft-bodied robot to achieve the capability of physiological stimuli monitoring, micropressure monitoring, soft grabbing, etc. Our rapid-response, low detection limit, and high-sensitivity capacitive flexible tactile sensor with a novel 3D porous dielectric layer could be a prospective candidate for the wearable applications in real-time and high-accuracy portable healthcare monitoring devices, advanced human-machine interfaces, and intelligent robot perception systems.
近年来,在高灵敏度触觉传感器中探索的三维(3D)多孔导电复合材料因其独特的多孔结构和优异的机械灵活性、高相对介电常数和良好弹性等独特的物理特性而引起了广泛的关注。在此,我们报告了一种实用、高效、宏观的浸涂工艺,用于制造快速响应、低检测限、高灵敏度和高灵敏度的电容式柔性触觉传感器。比较研究了所开发器件的制造工艺、触觉感知机制和传感性能。由石墨烯纳米片/羧基功能化多壁碳纳米管/硅橡胶复合材料锚定在聚氨酯海绵骨架上构建的均匀 3D 杂化网络表现出显著改善的介电性能,从而实现了具有快速响应时间(约 45ms)、极低压力检测限(约 3Pa)、出色灵敏度(约 0.062kPa)和出色耐用性和稳定性的高性能电容式柔性触觉传感器,经过 2000 次循环后仍保持稳定。重要的是,这些柔性器件可用作可穿戴电子皮肤,并成功安装在人体皮肤或软体机器人上,以实现生理刺激监测、微压力监测、软性抓取等功能。我们的具有快速响应、低检测限和高灵敏度的电容式柔性触觉传感器具有新颖的 3D 多孔介电层,有望成为实时、高精度便携式医疗监测设备、先进的人机界面和智能机器人感知系统等可穿戴应用的候选者。
